Physiology

At birth, S. saturatus are ectothermic.[5] Development of endothermy occurs gradually as individuals grow, increasing both body mass and amount of body fur.[5] Individuals removed from their mother at 6 days of age lost body temperature at a faster rate than at 36 days, when individuals were able to maintain a high internal body temperature and determined to be homeothermic.[5] This 36-day mark is conveniently the age at which offspring leave their burrows.[5] Individuals remained homeothermic in response to a 2-day removal of food and water at 2-week intervals.[5] Even with this drastically reduced body mass, torpor was not induced.[5] Smaller individuals did become hypothermic, however, and were returned to the mother to be re-warmed.[5]

Daily energy expenditures showed a small but significant increase of 10% as litter size increased, across a range of 3 to 5 offspring, the norm for the species.[6] Body mass, time spent above ground and time spent foraging were not correlated.[6] For the large amount energy contained in the mother’s milk, changes in metabolism were small.[6] Body mass and age of offspring was independent of litter size.[6] The fact that daily energy expenditure does not vary with litter size suggests that other factors, such as habitat quality, affect number of offspring.[6]

S. saturatus have been noted to move in two distinct ways – walking (mean speed of .21 m/s) and running (mean speed of 3.63 m/s).[7] 26.9% of total time spent daily above ground was spent walking, while only 3.6% was spent running.[7] It is noted that individuals run at their maximum aerobic speed of 3.6 m/s instead of the more maintainable minimum running pace of 2 m/s in order to minimize predation.[7]S. saturatus moved an average of 5 km/day – 1.5 km walking and 3.3 km running.[7] This considerable distance required 28.75 kJ/day of net added energy cost to do so, a 29% increase above BMR and 13% of daily energy expenditure.[7]

Behavior

Examination of alarm calls in response to Canis lupus familiaris among several species of ground squirrels showed that S. saturatus have a dialect of their own.[4] Vocalizations were distinct, and could be identified 100% of the time by a discriminant source.[4] This suggests that vocalizations can be used in addition to genetics and morphology to differentiate and designate species.[4]